Project description:We report development of a mechanism-based technique, Aza-IP, that utilizes the stable covalent linkage formed in vivo between an RNA methyltransferase (m5C-RMT) and 5-azacytidine (5-aza-C) incorporated within the target RNA to enable specific target enrichment, coupled with high-throughput sequencing to provide target identification. We apply Aza-IP to two enzyme types, DNMT2 and NSUN2, the latter with important roles in fertility, intellectual ability, stem cells and cancer. For both, Aza-IP provided >200-fold enrichment of their known human tRNA targets. For NSUN2, we reveal many novel tRNA and non-coding RNA targets, all linked to NSUN2 nucleolar localization, greatly increasing the potential repertoire underlying loss-of-function pathologies. Strikingly, we observe a C>G transversion ‘signature’ specifically at the target cytosine, which enables the identification of the exact target cytosine within the RNA in the same experiment. The general design of Aza-IP involves nine steps: 1) Expression of an epitope-tagged m5C-RMT derivative (or use of an antibody capable of immuno-precipitating the RNA-bound enzyme), 2) cell growth in the presence of 5-aza-C, which incorporates at low/moderate levels into nascent RNA, 3) cell lysis, 4) immuno-precipitation of the subject m5C-RMT, a portion of which is covalently attached to target RNAs bearing 5-aza-C, 5) stringent washing to remove RNA contaminants, 6) RNA fragmentation, release and purification, 7) ligation of adaptor oligos to the RNA, and the creation of a cDNA library in a manner that enables strand-specific assignments, 8) cDNA sequencing, and 9), mapping and examination of sequence reads to define RNA targets and site of cross-linking/catalysis.

Project description:Dnmt2 and NSun2 are (cytosine-5) RNA methyltransferases. Using CRISPR/Cas9 we created null mutations in Dnmt2 and NSun2 genes in Drosophila melanogaster. We also ectopically expressed a wild type and catalytically inactive Dnmt2 form in the Dnmt2 mutant background. RNA bisulfite sequencing was used to follow RNA methylation at partical tRNA substrates.

Project description:Mutations in the cytosine-5 RNA methyltransferase NSun2 can cause Intellectual Disability (ID) and symptoms commonly found in patients with Dubowitz syndrome. By analysing gene expression data with the global cytosine-5 RNA methylome in NSun2-deficient mice, we find that loss of cytosine-5 RNA methylation increases the fragmentation of transfer RNAs (tRNA) leading to an accumulation of 5M-bM-^@M-^Y halves. Cleavage of tRNAs by Angiogenin is a common cellular stress response to silence translational programmes, and we show that Angiogenin binds tRNAs lacking site-specific NSun2-methylation with higher affinity. Furthermore, cells lacking functional NSun2 up-regulate stress markers, and deletion of NSun2 compromises cellular survival in response stress stimuli including UV-light and oxidative stress. The decreased tolerance of NSun2 null cells towards oxidative stress can be rescued through inhibition of Angiogenin. In conclusion, cytosine-5 RNA methylation is an essential post-transcriptional mechanism during cellular stress responses and NSun2-mediated tRNA methylation protects from Angiogenin-dependent stress-induced RNA cleavage. RNA Methylation profiling by high throughput sequencing small non-coding RNA profiling by high throughput sequencing Pol III Chromatin-IP profiling by high throughput sequencing

Project description:Autosomal-recessive loss of the NSUN2 gene has been recently identified as a causative link to intellectual disability disorders in humans. NSun2 is an RNA methyltransferase modifying cytosine-5 in transfer RNAs (tRNA). Whether NSun2 methylates additional RNA species is currently debated. Here, we adapted the individual-nucleotide resolution UV cross-linking and immunoprecipitation method (iCLIP) to identify NSun2-mediated methylation in RNA transcriptome. We confirm site-specific methylation in tRNA and identify messenger and non-coding RNAs as potential methylation targets for NSun2. Using RNA bisulfite sequencing we establish Vault non-coding RNAs as novel substrates for NSun2 and identified six cytosine-5 methylated sites. Furthermore, we show that loss of cytosine-5 methylation in Vault RNAs causes aberrant processing into argonaute-associating small RNA fragments (svRNA). Thus, impaired Vault non-coding RNA processing may be an important contributor to the etiology of NSUN2-deficieny human disorders. mRNA-seq in Embryonic kidney (HEK293) cells transfected with siRNA against Nsun2 vs control

Project description:Autosomal-recessive loss of the NSUN2 gene has been recently identified as a causative link to intellectual disability disorders in humans. NSun2 is an RNA methyltransferase modifying cytosine-5 in transfer RNAs (tRNA). Whether NSun2 methylates additional RNA species is currently debated. Here, we adapted the individual-nucleotide resolution UV cross-linking and immunoprecipitation method (iCLIP) to identify NSun2-mediated methylation in RNA transcriptome. We confirm site-specific methylation in tRNA and identify messenger and non-coding RNAs as potential methylation targets for NSun2. Using RNA bisulfite sequencing we establish Vault non-coding RNAs as novel substrates for NSun2 and identified six cytosine-5 methylated sites. Furthermore, we show that loss of cytosine-5 methylation in Vault RNAs causes aberrant processing into argonaute-associating small RNA fragments (svRNA). Thus, impaired Vault non-coding RNA processing may be an important contributor to the etiology of NSUN2-deficieny human disorders. Identification of Nsun2 targets by miCLIP in Embryonic kidney (HEK293) cells

Project description:Post-transcriptional regulatory mechanisms are crucial for protein synthesis during spermatogenesis and often organized by the chromatoid body. Chromatoid bodies are large cytoplasmic ribonucleoprotein granules, whose precise function and composition remain unclear. Here, we identify NSun2 as a novel component of the chromatoid body, and further show that this RNA methylase is essential for germ cell differentiation in the mouse testis. Lack of NSun2 leads to down-regulation of genes controlling RNA processing and post-transcriptional repression pathways, including Ddx4, Mili, Piwil1 (Miwi) and Tudor domain containing (Tdrd) proteins. Germ cell differentiation was blocked specifically at the pachytene stage by lack of NSun2, as spermatogonial and Sertoli cells were unaffected in knockout mice. We observed the same phenotype when we simultaneously deleted NSun2 with Dnmt2, the only other characterized cytosine-5 RNA methyltransferase to date, indicating that Dnmt2 was not functionally redundant for NSun2 in spermatogonial stem cells or Sertoli cells. Thus, our data indicate that RNA methylation pathways play an essential role in male germ cell differentiation. Four sample groups: Testes from Wild-type and NSun2 knock out mice at 15 and 49 days; 6 samples in each group

Project description:We report high resolution transcriptome-wide RNA cytosine methylome of Mouse Embryonic Fibroblasts (MEFs) revealed by an optimized new RNA bisulfite sequencing approach. Comparison of RNA methylation profile from wild-type and Dnmt2 -/- MEFs shows that only C38 in three tRNAs (tRNA-Asp, Gly and Val) is the target of Dnmt2 in MEFs at normal conditions.

Project description:Mutations in the cytosine-5 RNA methyltransferase NSun2 can cause Intellectual Disability (ID) and symptoms commonly found in patients with Dubowitz syndrome. By analysing gene expression data with the global cytosine-5 RNA methylome in NSun2-deficient mice, we find that loss of cytosine-5 RNA methylation increases the fragmentation of transfer RNAs (tRNA) leading to an accumulation of 5’ halves. Cleavage of tRNAs by Angiogenin is a common cellular stress response to silence translational programmes, and we show that Angiogenin binds tRNAs lacking site-specific NSun2-methylation with higher affinity. Furthermore, cells lacking functional NSun2 up-regulate stress markers, and deletion of NSun2 compromises cellular survival in response stress stimuli including UV-light and oxidative stress. The decreased tolerance of NSun2 null cells towards oxidative stress can be rescued through inhibition of Angiogenin. In conclusion, cytosine-5 RNA methylation is an essential post-transcriptional mechanism during cellular stress responses and NSun2-mediated tRNA methylation protects from Angiogenin-dependent stress-induced RNA cleavage.

Project description:Autosomal-recessive loss of the NSUN2 gene has been recently identified as a causative link to intellectual disability disorders in humans. NSun2 is an RNA methyltransferase modifying cytosine-5 in transfer RNAs (tRNA). Whether NSun2 methylates additional RNA species is currently debated. Here, we adapted the individual-nucleotide resolution UV cross-linking and immunoprecipitation method (iCLIP) to identify NSun2-mediated methylation in RNA transcriptome. We confirm site-specific methylation in tRNA and identify messenger and non-coding RNAs as potential methylation targets for NSun2. Using RNA bisulfite sequencing we establish Vault non-coding RNAs as novel substrates for NSun2 and identified six cytosine-5 methylated sites. Furthermore, we show that loss of cytosine-5 methylation in Vault RNAs causes aberrant processing into argonaute-associating small RNA fragments (svRNA). Thus, impaired Vault non-coding RNA processing may be an important contributor to the etiology of NSUN2-deficieny human disorders.

Project description:Autosomal-recessive loss of the NSUN2 gene has been recently identified as a causative link to intellectual disability disorders in humans. NSun2 is an RNA methyltransferase modifying cytosine-5 in transfer RNAs (tRNA). Whether NSun2 methylates additional RNA species is currently debated. Here, we adapted the individual-nucleotide resolution UV cross-linking and immunoprecipitation method (iCLIP) to identify NSun2-mediated methylation in RNA transcriptome. We confirm site-specific methylation in tRNA and identify messenger and non-coding RNAs as potential methylation targets for NSun2. Using RNA bisulfite sequencing we establish Vault non-coding RNAs as novel substrates for NSun2 and identified six cytosine-5 methylated sites. Furthermore, we show that loss of cytosine-5 methylation in Vault RNAs causes aberrant processing into argonaute-associating small RNA fragments (svRNA). Thus, impaired Vault non-coding RNA processing may be an important contributor to the etiology of NSUN2-deficieny human disorders.